Elevator

ABSTRACT

An elevator includes an elevator motor; a motor drive for the elevator motor having a frequency converter comprising a rectifier bridge, an inverter bridge and a DC link in between, which frequency converter is controlled via a controller, the rectifier bridge being connected to AC mains via three feed lines comprising chokes, and the rectifier bridge being realised via controllable semiconductor switches; a contactor being located between the feed lines and AC mains; a backup power supply at least for emergency drive operation; and an emergency control for performing an automatic emergency drive. The backup power supply is via a first switch connectable with only a first of said feed lines. A second and/or third of the feed lines is, via a second switch, connectable as power supply to a car door arrangement, the first switch, as well as the second switch, are controlled by the emergency control, and the emergency control is connected to a manual drive circuit having a manual drive switch for a manual rescue drive.

The present invention relates to an elevator comprising an elevator motor, a motor drive for the elevator motor having a frequency converter comprising a rectifier bridge, an inverter bridge and a DC link in between, which frequency converter is controlled via a controller, the rectifier bridge being connected to mains via three feed lines comprising chokes, whereby the rectifier bridge is being realised via controllable semiconductor switches so that it is able to refeed electricity into mains during generator mode of the elevator or elevator group. Further, the elevator has a contactor being located between the feed lines and mains as well as a backup power supply at least for emergency drive operation. To effect an emergency drive, the elevator comprises an emergency control for performing an automatic emergency drive, which emergency control might be a separate component but is preferably integrated with the controller. For feeding power to the DC link the backup power supply is via a first switch connectable with only a first of said feed lines and the necessary Dc link voltage is provided via a boost activity of at least one of the semiconductor switches of the rectifier bridge connected with the first feed line and the at least one choke provided in the first feed line.

The controller regularly also controls the elevator brakes of the elevator to release them in normal operation as well as during an emergency drive. The backup power supply which is regularly realized via a battery may also be formed by other power supplies as e.g. supercapacitors. This technology forms the background of the invention. Such kind of elevator is disclosed in the WO 2008/100259 A1.

It is object of the present invention to provide an elevator which facilitates and allows an automatic as well as manual emergency drive to release trapped passengers.

The object is solved with an elevator according to claim 1. The object is further solved with a method according to claim 16. Preferred embodiments of the invention are subject matter of the correlated dependent claims. Preferred embodiments of the invention are also described in the specification and drawings.

According to the invention, the second and/or third of said feed lines is via a second switch connectable to a power supply of an elevator car door, whereby the first switch connecting the backup power supply to the first feed line as well as the second switch connecting the power supply of the elevator car door are controlled by the emergency control. The emergency control again is connected to a manual drive arrangement having a manual drive switch for manual rescue drive.

This inventive solution enables the use of the rectifier bridge on one hand to act as a booster in connection with a choke in the first feed line to transform the DC voltage of the backup power supply, hereinafter battery, to the required DC link voltage and the second and third feed line are simultaneously used to provide alternating current as power supply for the elevator car door which power supply is connected via the second switch to the second and/or third feed line. Thus, the emergency control which is usually integrated in the controller is able to release the elevator brakes and to start rotating the elevator motor to move the elevator car to the adjacent landing of the elevator. When the elevator car has arrived at the landing, the emergency control is via the second and/or third feed line able to supply the necessary power for the elevator car door to open it so that the trapped passengers can be released. Of course, the emergency control feeds power for the elevator car door also during emergency drive, to provide closing torque to keep the doors closed. The rectifier bridge which is a modulated rectifier bridge comprising of semiconductor switches controlled by the controller is therefore able to simultaneously fulfil the task of increasing (boosting) the DC voltage for the DC link as well as to provide the AC voltage for the elevator car door. The emergency control is thereby connected to a manual drive arrangement having a manual drive switch for the manual rescue drive which preferably enables the emergency control and/or the controller to be provided with power from the battery so that it is able to release the elevator brakes and to rotate the elevator motor preferably as long as the manual drive switch is pushed. There may also be more than one drive switch in the manual drive circuit, for example separate mode a selection switch and then separate manual drive switch.

Thus, the manual rescue drive can easily be performed. Of course, the elevator also comprises the automatic emergency drive function which is automatically performed by the emergency control in case of a power failure of (public) AC mains. Only in case the automatic emergency drive function does not work, e.g. because the controller gets no supply power and operating state of the elevator is therefore undefined, for example, elevator car position may be unknown, the emergency drive can be initiated by the manual drive arrangement by pushing the manual drive switch.

In a preferred embodiment of the invention, the backup power supply is connected to the DC link via a DC/DC converter, preferably in flyback topology. Via this measure, the capacitor of the DC link can be charged up to a sufficient voltage level before connecting the first feed line to the backup power supply to perform the boost action for the DC link. The advantage of the DC/DC converter is that the current provided by the DC/DC converter to the DC capacitor is limited so that the charge current peak which is present at the start of the charge up of the capacitor does not harm the DC/DC converter, the battery or the first switch. Furthermore, by the fact that now the DC link is charged up by the DC/DC converter and the battery to a certain level, the current is limited when the semiconductors of the rectifier bridge connected to the first feed line begin the boosting of the battery voltage to the DC link voltage. If this action would start with an unloaded capacitor, the high initial current might harm the corresponding semiconductors of the rectifier bridge.

In a preferred embodiment, the DC/DC converter is bidirectional and is configured on one hand to generate a DC voltage for the DC link which is higher than the battery voltage, and on the other hand the DC/DC converter is configured to form a charging circuit for the battery fed from the DC link. Thus, the DC/DC converter has two functions, i.e. to pre-charge the capacitor in case of mains power off so as to enable the above-mentioned emergency drive action and on the other hand to charge the battery during normal operation of the elevator. Via this measure, it is also ensured that the battery capacity is high enough in any case of mains power off.

Preferably, the manual drive circuit is disposed in a remote control unit outside of elevator shaft, so that the person performing the manual rescue drive does not need to enter the elevator shaft.

In a preferred embodiment of the invention a transformer is arranged between the car door arrangement (door operator) and the second switch, so that the supply voltage can be easily adapted to the requirements of the door arrangement.

In an alternative embodiment, the DC/DC converter is one directional such that is it configured only to charge the battery from the DC link. This means that the DC/DC controller only has one MOSFET transistor in the DC link side of the transformer, and the other MOSFET transistor in the battery side is not needed.

Preferably, the DC/DC converter comprises at least one PWM controller, preferably two PWM controllers, namely one on each side, which is/are controlled via the controller. The programs to control the PWM controllers are then preferably stored in the controller so that it is optimized for battery charging during normal operation as well as for pre-charging the capacitor in the DC link during emergency drive.

In this connection it is to be mentioned that preferably a capacitor is provided in the DC link which is the normal frequency converter topology to minimize voltage ripple in the DC link.

In a preferred embodiment of the invention, the controller comprises an auxiliary power input being connectable to the backup power supply. The DC link usually supplies power to the controller. Anyway, during periods of non-use, e.g. during nights as well as in any case of mains power off, the voltage of the DC link might drop so that is not any longer sufficient to form a power supply for the controller, at least to perform the emergency drive. In this case, this auxiliary power input is advantageous as it can be connected to the backup power supply during mains power off to ensure that all necessary operations in connection with an emergency drive, independent whether it is an automatic emergency drive or a manual emergency drive, can be performed.

Preferably, a second DC/DC converter is connected with the auxiliary power input. This has the advantage that the second DC/DC converter can boost or reduce the incoming voltage to the voltage level which is adapted as supply voltage for the controller. In this connection it is advantageous if the second DC/DC converter is a PWM-controlled which enables a wide input voltage range. In this case it is preferable that the PWM of the second DC/DC converter has its own separated control as the function of the controller is not ensured in case of mains power off because of missing supply voltage.

In a preferred embodiment of the invention, the DC/DC converter of the battery is connected to the auxiliary power input, preferably to the second DC/DC converter, preferably via a diode. In this case, the controller may receive the energy from the DC/DC converter in a mains power off situation when the DC/DC converter is starting to charge up the capacitor in the DC link which provides a DC voltage which is higher than that needed by the controller so that the voltage level can be adapted to the correct voltage for the controller by the second DC/DC converter. By providing the diode between the DC/DC converter and the second DC/DC converter, it can be ensured that the voltage is only flowing in the direction from the DC/DC converter to the second DC/DC converter and thus to the auxiliary power input of the controller. So the second DC/DC converter receives power from output of the DC/DC converter when it has higher voltage than the battery, otherwise second DC/DC converter receives power from the battery via the third switch whereby the first and second diodes act as selector or the highest input voltage for the second DC/DC converter.

Preferably, an activation circuit is provided between the backup power supply and the auxiliary power input, in which activation circuit a third switch is provided which is controlled via the emergency control (controller) as well as via the manual drive arrangement. Via this measure, power supply from the battery directly to the auxiliary power input—or to the second DC/DC converter connected to it—happens via this activation circuit. If the controller has still enough power, the emergency control closes the third switch which is preferably a semiconductor switch and thus it is ensured that the battery is connected with the auxiliary power input of the controller, possibly via the second DC/DC converter to ensure a correct voltage level. Thus, in any case of mains power off, a reliable function of the controller and the emergency control is ensured via this activation circuit and the controller can keep awareness of current elevator status. On the other hand, if the voltage level for the function of the emergency control (controller) is too low, the third switch cannot be closed via the emergency control itself as done during an automatic emergency drive. In this case, via pushing a manual drive switch in the manual drive arrangement, the third switch can be closed so that enough power is provided for the emergency control (controller) to perform a manual emergency drive which also requires that via the emergency control (controller) the brakes are released. In some embodiments of the manual emergency drive, also the elevator motor is rotated and after arrival at a landing the car doors are opened. The emergency control (controller) is thus connected in any case to the battery via the activation circuit. The activation circuit is thereby closed either via the automatic emergency drive function of the emergency control itself or via the manual emergency drive function of the manual drive arrangement (pushing a manual drive switch in a manual drive circuit of the manual drive arrangement).

Preferably, the third switch is connected to the second DC/DC converter via a diode, which ensures that power only flows one way to the auxiliary power input of the controller. As preferably also the first DC/DC converter is connected to the auxiliary power input—or second DC/DC converter—via a diode the power is fed to the auxiliary power input either from the DC/DC converter or from the activation circuit, i.e. which source provides the higher supply voltage level.

Preferably the second DC/DC converter is PWM-controlled enabling a wide input voltage range.

Preferably, at least one capacitor is connected between the positive and negative branch of the DC link. This capacitor smoothes the ripple in the DC voltage of the DC link. Preferably this capacitor may be formed by a series connection of two capacitors in which case the connection point of the two capacitors can be used as a neutral point of the DC link.

Preferably, the third switch in the activation circuit is controlled via at least one semiconductor switch controlled by the emergency control as well as by the manual drive arrangement. That means the emergency control during its automatic emergency drive function controls the third switch to close so that power is fed from the battery to the auxiliary power input of the emergency control (controller).

Preferably, parallel to the semiconductor switch, a fourth switch in a manual drive circuit of a manual drive arrangement is connected, which is preferably an opto-coupler. If the emergency control is not able to switch on the third switch via the semiconductor switch, the switching of the third switch can be realized by the fourth switch which is activated via the manual drive circuit by pushing the manual drive switch located therein. The embodiment of the fourth switch as an opto-coupler has the advantage that the manual drive circuit of the manual drive arrangement is galvanically isolated from the circuit of the elevator drive.

Preferably, the manual drive circuit in which the activating switch is connected comprises a second backup power supply, preferably a second battery. The manual drive circuit is connected to the third switch preferably via the opto-coupler. As the manual drive circuit is galvanically isolated from the whole motor drive and controller, it is preferable that the separated manual rescue switch has its own second backup power supply, preferably battery, which enables a reliable use of the manual drive arrangement in case of mains power off.

Preferably, at least one capacitor is connected between the positive and negative branch of the DC link which enables a smooth DC link voltage preferably when the DC link voltage is boosted via the connection of the backup power supply to the first feed line in connection with its choke and the corresponding semiconductor switches of the rectifier bridge.

It is further to be mentioned that the semiconductor switches of the rectifier bridge connected to the first feed lines are operated during boost operation preferably with a frequency of 100 Hz-10 kHz to provide in connection with the choke located in the first feed line the sufficient DC voltage for the DC link. Hereby, the semiconductor switch of the lower half-bridge controls via its switching cycle the voltage, which is based on the inductance voltage peaks of the choke(s), which voltage peaks run via the anti-parallel diode of the upper semiconductor switch to the positive branch of the DC link. Of course via this measure a voltage is boosted which is much higher than the feed voltage of the backup power supply.

Preferably, the semiconductor switches of the rectifier bridge are provided with antiparallel diodes, so that easier voltage boosting function in the above sense is enabled.

The invention also refers to a method for performing a rescue operation in an elevator according to the type which is described above. This method works as follows: In case of mains power off, the contactors are opened so that the feed lines are no longer connected with AC mains. Then, the backup power supply is initiated to feed direct current to the DC link via the DC/DC converter which boosts the DC voltage to a level which is adapted for the DC link (regularly several hundred volts) from the battery voltage level (regularly 20 to 63 V). This pre-charges the capacitor in the DC link.

The emergency control (controller) then energizes an activation circuit via the emergency control or via a manual drive circuit, which activation circuit connects the backup power supply to an auxiliary power input of the emergency control to selectively perform an automatic or manual emergency drive. The backup power supply is connected to the first feed line and the lower semiconductor of the rectifier bridge connected to the first feed line is controlled to switch, e.g. with a frequency between 100 Hz and 100 kHz which is optimal for voltage boosting. In the automatic rescue drive, the emergency control energizes the elevator brakes to release by controlling power supply from the DC link to the brakes and begins rotating the elevator motor via control of the inverter bridge, whereas in the manual rescue drive, the emergency control at least energizes the elevator brakes to release by controlling power supply from the DC link to the brakes, in which case the car may e.g. move by its gravitational force.

Via the semiconductor switches connected to the second and/or third feed line an AC voltage is created in the second and/or third feed line which is/are connected as power supply to the door arrangement of the elevator car.

After the elevator car has reached a landing zone the car doors are opened to release the passengers with the supply voltage fed via the second and/or third feed line.

Via the semiconductor switches of the rectifier bridge connected to the second and third feed line, an AC voltage is created in these feed lines, and the second and/or third feed line is connected via a second switch to the door arrangement, i.e. door drive and door controller of the elevator car as a power supply. If only one of the second or third feed line is connected as a power supply to the car arrangement the other pole for the power supply has to be created by a neutral voltage level of the DC link. This neutral point could be created for example by using the connection point between two capacitors which are connected in series between the two branches of the DC link. Thus either the power supply is between the second or third feed line on one hand and the neutral point on the other hand or between the second and third feed line. After the elevator car has reached a landing zone, the car doors are then opened via the connection of the second and/or third feed line to the door drive of the elevator car. Thus, an automatic as well as manual emergency drive for releasing trapped passengers is possible in an economical way.

Preferably, a transformer is arranged between the car door arrangement and the second switch such that the AC voltage created in the second and third feed lines is supplied to the transformer and transformed to an adapted voltage for the door arrangement.

Preferably, a manual drive switch in a manual drive arrangement is pressed to energize the activation circuit which leads to a connection of the backup power supply with the (auxiliary) power input of the controller/emergency control. This enables the activation of the controller even if it is in an unpowered state via manual operation of the manual drive arrangement.

Preferably, the DC/DC converter which is used to pre-charge the capacitor in the DC link before connecting the backup power supply to the first feed line is used in a normal elevator operation as a charging circuit for the backup power supply. Thus, the different functions can be realized with a minimum of hardware components.

It shall be clear that the controller may be a separate or integrated part of the elevator control, and it may comprise or being connected with the control of the elevator brakes to release the elevator brakes during an emergency drive. Hereinafter, the control of the elevator brakes is described to be integrated with the controller, but it is clear that it may be a separate control component connected to the elevator control and/or controller. The controller is usually a digital signal processor which is connected by control lines with the semiconductors of the rectifier bridge as well as of the inverter bridge and it has inputs for obtaining status data of the elevator motor as velocity and electric values of the inverter bridge and of the elevator motor.

Above, the power supply to the emergency control (controller) in case of mains power off has been realized via its auxiliary power input. Of course, the auxiliary input is preferable but not really necessary to perform the above functions. In this case the power is fed from the DC/CD converter or activation circuit to the (normal) power input of the emergency control (controller).

The semiconductor switches of the rectifier bridge and/or inverter bridge may preferably be IGBTs or MOSFETs or SiC MOSFETs.

It shall be clear for the skilled person that the above-mentioned embodiments may be combined with each other arbitrarily.

Following terms are used as synonyms: backup power supply—battery; rectifier bridge—modulated rectifier bridge; DC/DC converter—first DC/DC converter; capacitor—smoothing capacitor; elevator brake—motor brake; landing zone indicator—door zone indicator; fourth switch—opto coupler;

The invention is hereinafter described via a preferred embodiment in connection with the drawings.

FIG. 1 shows an electric diagram of the motor and brake drive section of an elevator including automatic and manual emergency drive components, and

FIG. 2 shows an electric diagram similar to FIG. 1 with a simplified charging arrangement for the backup power supply.

FIG. 1 shows an elevator 10 comprising an elevator motor 12 which is controlled by an elevator drive 14 which is embodied as a frequency converter comprising a modulated rectifier bridge 16 consisting of semiconductor switches with antiparallel diodes, an inverter bridge 18 and a DC link 20 in between. The DC link 20 comprises a smoothing capacitor 22. The elevator motor 12 comprises preferably a traction sheave 24 over which a hoisting rope 26 is running carrying an elevator car 28 and optionally a counterweight 30. Alternatively, the hoisting rope 26 may be connected with the underside of the car to build a closed loop (with or without counterweight 30). Further, the elevator motor 12 comprises two parallel elevator brakes 32 a, 32 b. Finally, a controller 34 is provided which additionally forms an emergency control 35 of the elevator drive 14. The controller 34 controls the semiconductor switches 17 of the rectifier bridge 16, the semiconductor switches of the inverter 18, the elevator brakes 32 a, 32 b and it is connected with a landing zone indicator 36 showing whether or not the elevator car has arrived a landing zone of the elevator 10. Preferably the controller gets input of the electrical values of the inverter bridge and elevator motor and eventually a tachometer signal of an encoder at the motor shaft or traction sheave.

The rectifier bridge 16 is connected via three feed lines 38 a-c to a main contactor 40. The three feed lines 38 a-c are connected via the main contactor 40 with AC mains 42, i.e. with normally a three-phase AC public network. In each feed line 38 a-38 c, two chokes 44 a, 44 b are located. Between the feed lines 38 a-38 c, a capacitor bridge 46 is connected which in connection with the chokes 44 a and 44 b act as an AC line filter. The elevator drive 14 comprises a backup power supply 48 preferably in form of a battery which is connected to a DC/DC converter 50, preferably in a flyback topology. The DC/DC converter 50 comprises on both sides a PWM controller which is controlled by the controller 34. The battery 48 is connected via a first switch 52 to the first feed line 38 a. The first switch 52 also disconnects the capacitor bridge 46 from the first feed line 38 a simultaneously with connection to the battery 48. The second and third feed line are connected with second switches 54 a, 54 b with door arrangement 56 comprising a door controller as well as a door drive and the car door.

The controller 34 has preferably an auxiliary power input 58 connected preferably to a second DC/DC converter 60. The second DC/DC converter 60 acts as a kind of voltage regulator for the auxiliary power input 58 of the controller 34.

While the first branch of the DC/DC converter 50 is connected with the battery 48, the second branch is connected to the DC link 20. Furthermore, additionally the second branch of the DC/DC converter 50 is connected via a first diode 62 to the second DC/DC converter 60 at the auxiliary power input 58 of the controller 34. The battery 48 is via an activation circuit 64 directly connected to the second DC/DC converter 60, and thus to the auxiliary power input 58 of the controller 34. The activation circuit 64 comprises a third switch 66 and a second diode 68. So the second DC/DC converter 60 receives power from output of the DC/DC 50 converter when it has higher voltage than the battery 48, otherwise second DC/DC converter 60 receives power from the battery 48 via the third switch 66 whereby the first and second diodes 62 and 68 act as selector or the highest input voltage for the second DC/DC converter 60.

In this activation circuit 64 the third switch 66 is preferably a semiconductor switch which is activated via a boost transistor 72 connected to the gate of the third switch 66. The boost transistor 72 is controlled either via a transistor 70 (or other semiconductor switch) which is controlled via the controller 34 in case of an automatic emergency drive. Or the boost transistor 72 is controlled a fourth switch 74 preferably in form of an opto-coupler. This fourth switch 74 is connected in parallel to the transistor 70 and is comprised in a manual drive circuit 78 of a manual drive arrangement 76. The manual drive circuit 78 comprises a second backup power supply (battery) 80 and a manual drive switch 82. The manual drive circuit 78 is connected to the other components of the elevator drive 14 via the opto-coupler 74. This means that the third switch 66 in the activation circuit 64 is controlled either via the transistor 70 or via the opto-coupler 74 of the manual drive circuit 78, which two alternative ways correspond to an automatic or manual emergency drive of the elevator car, particularly in case of AC mains power off. The function of the elevator 10 in an emergency case is carried out hereinafter: In case of a power off of the mains 42, the main contactor 40 is opened. Now, there are two cases.

The first case is that the voltage level in the DC link 20 is sufficiently high enough for the controller 34 to operate. In this case, the transistor 70 controlled by the controller 34, i.e. the emergency control 35 thereof, is activated which closes the third switch 66 in the activation circuit 64 so that the battery 48 is via the second DC/DC converter 60 connected to the auxiliary power input 58 of the controller 34. This power supply via the activation circuit 64 to the auxiliary power input 58 enables the controller 34 to operate properly. Now the controller 34 controls the two PWM controllers of the DC/DC converter 50 to charge up the smoothing capacitor 22 in the DC link 20. After the voltage in the DC link 20 has reached a sufficient level, the first switch 52 is closed by the controller 34 so that the battery 48 is connected to the first feed line 38 a. Simultaneously, the capacitor bridge 46 is separated from the first feed line 38 a. Now, a DC voltage is connected to the first feed line 38 a and the lower semiconductor 17 f of the rectifier bridge 16 is controlled to open and close in a frequency of about 100 Hz to 10 kHz. This leads to corresponding voltage peaks of the chokes 44 a and 44 b in the first feed line 38 a which voltage flows via the antiparallel diode of the upper semiconductor 17 c to the DC link 20 and charges it to a desired voltage level. Via the fact that the smoothing capacitor 22 in the DC link has been pre-charged by the DC/DC converter 50, the current flowing through the antiparallel diode 17 c is not too high for it to be harmed. Now, also the DC link 20 has a sufficient voltage level so that the second switches 54 a, 54 b can be closed to energize the door arrangement 56 to ensure that the car doors are closed during emergency drive. The controller 34 now controls the elevator brakes 32 a and 32 b to release and controls the semiconductors in the inverter bridge 18 to rotate the elevator motor 12. When the elevator car 28 has reached the level of a door zone, this is signalized to the controller 34 via landing zone indicator 36. Then the controller 34 stops rotating the elevator motor 12 and de-energizes the elevator brakes 32 a, 32 b enabling them to grip and keep the traction sheave 24 stopped. Now, the controller 34 initiates the door controllers and door drives of the door arrangement 56 to open the car door which is possible via the power supply via the second and third feed lines 38 b and 38 c which are connected to the door drive and door controller via second switch 54 a, 54 b. As normally the car doors connectors are coupled to the corresponding landing doors both are opened and the trapped passengers can be released.

If in a second situation the voltage level in the DC link at the beginning of the emergency drive is not sufficiently high for the controller 34 to work, the controller 34 is not able to activate the transistor 70 to close the third switch 66 in the activation circuit 64. In this case, a maintenance person or an operator has to push a manual drive switch 82 in the manual drive circuit 78 which closes the fourth switch 74 parallel to the transistor 70 and thus closes via boost transistor 72 the third switch 66 connecting the battery 48 to the second DC/DC converter 60 at the auxiliary power input 58 of the controller 34 via the second diode 68. Now, the controller 34 is able to work and to start the necessary steps for performing the manual emergency drive as mentioned above with starting pre-charging the capacitor 22 in the DC link 20 via the DC/DC converter 50. Usually the manual drive switch has to be kept pushed until the car has arrived at a landing and the doors are opened so that the trapped persons may be released.

The automatic emergency drive maybe started automatically or controlled via a remote maintenance centre, which is connected to the controller 34 (and/or the elevator control) via a public communication network.

An alternative embodiment shown in FIG. 2 is almost identical to FIG. 1 with the difference that the DC/DC converter 51 is only one directional such that is it configured only to charge the battery 48 from the DC link, but in contrast to FIG. 1 it is not able to feed boosted DC voltage to the DC link 20. In this case the DC/DC controller 51 only has one PWM controlled MOSFET transistor in the DC link side of the transformer, and the other MOSFET transistor in the battery side is not needed.

In this alternative embodiment, the initial charging of DC link takes place via a pre-charge line 83 in which a current limiting resistor and a third diode is connected. This pre-charge line is connected between the output of the third switch 64 and the positive branch DC+ of the DC link 20. This embodiment has the advantage of lower cost. Of course in this case the capacitor 22 can only be charged to the voltage level of the battery 48.

The capacitor 22 in the DC link 20 can also be formed by a series connection of two capacitors in which case the connection point of the two capacitors is used as a neutral point of the DC link, e.g. for connecting the door arrangement 56 between only one of the second or third feed line 38 b, 38 c and this neutral point.

The above elevator therefore allows automatic as well as manual emergency drive operation with a minimum of hardware components and with a high level of security and reliability.

The invention is not restricted to the disclosed embodiments but may be varied within the scope of the claims as attached.

LIST OF REFERENCE NUMBERS

-   10 elevator -   12 elevator motor -   14 elevator drive -   16 rectifier bridge -   18 inverter bridge -   20 DC link (DC+, DC−) -   22 smoothing capacitor -   24 traction sheave -   26 hoisting rope—a set of hoisting ropes -   28 elevator car -   30 counterweight -   32 a,b elevator brakes—motor brakes -   34 controller (including emergency control, e.g. being part of the     elevator control) -   35 emergency control -   36 landing zone indicator—door zone indicator -   38 a,b,c three feed lines to the rectifier bridge -   40 main contactor -   42 AC mains (public AC network) -   44 a first chokes in the feed lines -   44 b second chokes in the feed lines -   46 capacitor bridge -   48 backup power supply—battery -   50 (first) DC/DC converter -   52 first switch (relay) -   54 a,b second switch -   56 door arrangement (door drive with door controller and car door) -   58 auxiliary power input of the controller -   60 second DC/DC converter at auxiliary power input -   62 first diode between DC/DC converter and second DC/DC converter -   64 activation circuit -   66 third switch -   68 second diode -   70 transistor controlled by the controller -   72 boost transistor for third switch -   74 fourth switch—opto coupler -   76 manual drive arrangement -   78 manual drive circuit -   80 second backup power supply—second battery in the manual drive     circuit -   82 manual drive switch -   83 pre-charge line -   84 resistor -   86 third diode 

1. An elevator comprising: an elevator motor; a motor drive for the elevator motor having a frequency converter comprising a rectifier bridge, an inverter bridge and a DC link in between, the frequency converter being controlled via a controller, the rectifier bridge being connected to AC mains via three feed lines comprising chokes, and the rectifier bridge being realised via controllable semiconductor switches; a contactor located between the feed lines and the AC mains; a backup power supply, at least for emergency drive operation; and an emergency control for performing an automatic emergency drive, wherein the backup power supply is, via a first switch, connectable with only a first of said feed lines, wherein a second and/or third of said feed lines is, via a second switch, connectable as power supply to a car door arrangement, while the second and third feed lines are separated from the AC mains with the contactor, wherein the first switch, as well as the second switch, are controlled by the emergency control, and wherein the emergency control is connected to a manual drive circuit having a manual drive switch for a manual rescue drive.
 2. The elevator according to claim 1, wherein the emergency control is integrated with the controller.
 3. The elevator according to claim 1, wherein the backup power supply is connected to the DC link via a DC/DC converter.
 4. The elevator according to claim 3, wherein the DC/DC converter is bidirectional and is configured to generate a DC voltage for the DC link which is higher than the backup power supply voltage, and which DC/DC converter is further configured to be a charging circuit for the backup power supply fed from the DC link.
 5. The elevator according to claim 3, wherein the DC/DC converter is one directional and a pre-charge line is connected between the backup power supply and the positive busbar (DC+) of the DC link.
 6. The elevator according to claim 3, wherein the DC/DC converter comprises at least one PWM controller which is/are controlled via the controller.
 7. The elevator according to claim 1, wherein the controller comprises an auxiliary power input being connectable to the backup power supply.
 8. The elevator according to claim 7, wherein a second DC/DC converter is located in the auxiliary power input.
 9. The elevator according to claim 3 wherein the controller comprises an auxiliary power input being connectable to the backup power supply, wherein a second DC/DC converter is located in the auxiliary power input, and wherein the DC/DC converter is connected to the auxiliary power input, to the second DC/DC converter, via a first diode.
 10. The elevator according to claim 7, wherein an activation circuit is provided between the backup power supply and the auxiliary power input, in which activation circuit a third switch is provided which is controlled via the emergency control and via the manual drive circuit.
 11. The elevator according to claim 7, wherein the third switch is connected to the second DC/DC converter via a second diode.
 12. The elevator according to claim 10, wherein the third switch is controlled via at least one transistor controlled by the emergency control.
 13. The elevator according to claim 12, wherein parallel to the transistor a fourth switch of a manual drive circuit is connected.
 14. The elevator according to claim 13, wherein the manual drive circuit comprises a second backup power supply and a manual drive switch, which manual drive circuit controls the third switch via an opto-coupler.
 15. The elevator according to claim 1, wherein the backup power supply is or comprises a battery.
 16. A method for performing a rescue operation in the elevator according to claim 1, comprising the following steps: in case of mains power off, the contactor is opened and the backup power supply is initiated to feed direct current to the DC link via a DC/DC converter; an activation circuit is energized via the emergency control or via a manual drive circuit, the activation circuit connecting the backup power supply with an auxiliary power input of the emergency control to selectively perform an automatic or manual emergency drive; the backup power supply is connected to the first feed line and the lower semiconductor of the rectifier bridge connected to the first feed line is controlled to switch with a frequency between 100 Hz and 100 kHz; in the automatic rescue drive, the emergency control energizes the elevator brakes to release by controlling power supply from the DC link to the brakes and begins rotating the elevator motor via control of the inverter bridge; and in the manual rescue drive, the emergency control at least energizes the elevator brakes to release by controlling power supply from the DC link to the brakes; via the semiconductor switches connected to the second and third feed line an AC voltage is created in the second and/or third feed line which is/are connected as power supply to the door arrangement of the elevator car; and after the elevator car has reached a landing zone the car doors are opened to release the passengers with the supply voltage fed via the second and/or third feed line.
 17. The method according to claim 16, wherein in the manual rescue drive the emergency control energizes the elevator brakes to release by controlling power supply from the DC link to the brakes and begins rotating the elevator motor via control of the inverter bridge.
 18. The method according to claim 17, wherein, if the emergency control has closed down so that the activation circuit is not energized by the emergency drive, a manual drive switch in a manual drive circuit is pressed which leads to closing of the activation circuit.
 19. A method for operating an elevator and designed to use the method for performing a rescue operation according to claim 16, wherein the DC/DC converter is used in normal elevator operation to charge the backup power supply.
 20. The elevator according to claim 3, wherein the DC/DC converter is one directional and a pre-charge line is connected between the backup power supply and the positive busbar (DC+) of the DC link via a third switch of an activation circuit. 